L-band geosynchronous SAR imaging degradations imposed by ionospheric irregularities

It is well known that the ionospheric scintillation caused by small-scale ionospheric irregularities is a major distortion source for low-frequency spaceborne synthetic aperture radar(SAR) imaging. For L-band geosynchronous earth orbit(GEO) SAR, the orbit height is ultra-high and the integration tim...

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Bibliographic Details
Published in:Science China. Information sciences 2017-06, Vol.60 (6), p.99-111, Article 060308
Main Authors: Ji, Yifei, Zhang, Qilei, Zhang, Yongsheng, Dong, Zhen
Format: Article
Language:English
Subjects:
Approximation
Computer Science
Fourier transforms
Image resolution
Information Systems and Communication Service
Ionosphere
Irregularities
Low earth orbits
L波段
Radar imaging
Research Paper
SAR成像
Synthetic aperture radar
Velocity
地球同步轨道
地球电离层
星载合成孔径雷达
电离层穿透点
电离层闪烁
退化
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Summary:It is well known that the ionospheric scintillation caused by small-scale ionospheric irregularities is a major distortion source for low-frequency spaceborne synthetic aperture radar(SAR) imaging. For L-band geosynchronous earth orbit(GEO) SAR, the orbit height is ultra-high and the integration time is ultra-long,thus ionospheric irregularities may cause more significant distortions on the imaging focusing. To evaluate this effect, the generalized ambiguity function(GAF) is employed to establish the analytical model. The imaging resolution can be studied by calculating the second moment of GAF. Furthermore, since the scanning velocity of the ionospheric penetration point(IPP) for GEO SAR is much slower than that of low earth orbit(LEO)SAR, the convection velocity of the ionospheric irregularities is no longer negligible. Taking this into account,we derive a more accurate expression of ionospheric irregularities' effect. The theoretical derivation is validated by numerical analyses and signal-level simulations.
ISSN:1674-733X
1869-1919
DOI:10.1007/s11432-016-9064-1